## ## This file is part of the libsigrokdecode project. ## ## Copyright (C) 2015 Josef Gajdusek ## ## This program is free software; you can redistribute it and/or modify ## it under the terms of the GNU General Public License as published by ## the Free Software Foundation; either version 2 of the License, or ## (at your option) any later version. ## ## This program is distributed in the hope that it will be useful, ## but WITHOUT ANY WARRANTY; without even the implied warranty of ## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ## GNU General Public License for more details. ## ## You should have received a copy of the GNU General Public License ## along with this program; if not, see . ## import sigrokdecode as srd import operator import collections from functools import reduce end_codes = ( 'Unknown', 'Charge Complete', 'Internal Fault', 'Over Temperature', 'Over Voltage', 'Over Current', 'Battery Failure', 'Reconfigure', 'No Response', ) class SamplerateError(Exception): pass def calc_checksum(packet): return reduce(operator.xor, packet[:-1]) def bits_to_uint(bits): # LSB first return reduce(lambda i, v: (i >> 1) | (v << (len(bits) - 1)), bits, 0) class Decoder(srd.Decoder): api_version = 3 id = 'qi' name = 'Qi' longname = 'Qi charger protocol' desc = 'Protocol used by Qi receiver' license = 'gplv2+' inputs = ['logic'] outputs = ['qi'] channels = ( {'id': 'qi', 'name': 'Qi', 'desc': 'Demodulated Qi data line'}, ) annotations = ( ('bits', 'Bits'), ('bytes-errors', 'Bit errors'), ('bytes-start', 'Start bits'), ('bytes-info', 'Info bits'), ('bytes-data', 'Data bytes'), ('packets-data', 'Packet data'), ('packets-checksum-ok', 'Packet checksum'), ('packets-checksum-err', 'Packet checksum'), ) annotation_rows = ( ('bits', 'Bits', (0,)), ('bytes', 'Bytes', (1, 2, 3, 4)), ('packets', 'Packets', (5, 6, 7)), ) def __init__(self): self.samplerate = None self.reset_variables() def reset_variables(self): self.counter = 0 self.prev = None self.state = 'IDLE' self.lastbit = 0 self.bytestart = 0 self.deq = collections.deque(maxlen = 2) self.bits = [] self.bitsi = [0] self.bytesi = [] self.packet = [] def metadata(self, key, value): if key == srd.SRD_CONF_SAMPLERATE: self.samplerate = value self.bit_width = float(self.samplerate) / 2e3 def start(self): self.out_ann = self.register(srd.OUTPUT_ANN) self.reset_variables() def packet_len(self, byte): if 0x00 <= byte <= 0x1f: return int(1 + (byte - 0) / 32) if 0x20 <= byte <= 0x7f: return int(2 + (byte - 32) / 16) if 0x80 <= byte <= 0xdf: return int(8 + (byte - 128) / 8) if 0xe0 <= byte <= 0xff: return int(20 + (byte - 224) / 4) def in_tolerance(self, l): return (0.75 * self.bit_width) < l < (1.25 * self.bit_width) def putp(self, data): self.put(self.bytesi[0], self.bytesi[-1], self.out_ann, [5, data]) def process_packet(self): if self.packet[0] == 0x01: # Signal Strength self.putp(['Signal Strength: %d' % self.packet[1], 'SS: %d' % self.packet[1], 'SS']) elif self.packet[0] == 0x02: # End Power Transfer reason = end_codes[self.packet[1]] if self.packet[1] < len(end_codes) else 'Reserved' self.putp(['End Power Transfer: %s' % reason, 'EPT: %s' % reason, 'EPT']) elif self.packet[0] == 0x03: # Control Error val = self.packet[1] if self.packet[1] < 128 else (self.packet[1] & 0x7f) - 128 self.putp(['Control Error: %d' % val, 'CE: %d' % val, 'CE']) elif self.packet[0] == 0x04: # Received Power self.putp(['Received Power: %d' % self.packet[1], 'RP: %d' % self.packet[1], 'RP']) elif self.packet[0] == 0x05: # Charge Status self.putp(['Charge Status: %d' % self.packet[1], 'CS: %d' % self.packet[1], 'CS']) elif self.packet[0] == 0x06: # Power Control Hold-off self.putp(['Power Control Hold-off: %dms' % self.packet[1], 'PCH: %d' % self.packet[1]], 'PCH') elif self.packet[0] == 0x51: # Configuration powerclass = (self.packet[1] & 0xc0) >> 7 maxpower = self.packet[1] & 0x3f prop = (self.packet[3] & 0x80) >> 7 count = self.packet[3] & 0x07 winsize = (self.packet[4] & 0xf8) >> 3 winoff = self.packet[4] & 0x07 self.putp(['Configuration: Power Class = %d, Maximum Power = %d, Prop = %d,' 'Count = %d, Window Size = %d, Window Offset = %d' % (powerclass, maxpower, prop, count, winsize, winoff), 'C: PC = %d MP = %d P = %d C = %d WS = %d WO = %d' % (powerclass, maxpower, prop, count, winsize, winoff), 'Configuration', 'C']) elif self.packet[0] == 0x71: # Identification version = '%d.%d' % ((self.packet[1] & 0xf0) >> 4, self.packet[1] & 0x0f) mancode = '%02x%02x' % (self.packet[2], self.packet[3]) devid = '%02x%02x%02x%02x' % (self.packet[4] & ~0x80, self.packet[5], self.packet[6], self.packet[7]) self.putp(['Identification: Version = %s, Manufacturer = %s, ' \ 'Device = %s' % (version, mancode, devid), 'ID: %s %s %s' % (version, mancode, devid), 'ID']) elif self.packet[0] == 0x81: # Extended Identification edevid = '%02x%02x%02x%02x%02x%02x%02x%02x' % self.packet[1:-1] self.putp(['Extended Identification: %s' % edevid, 'EI: %s' % edevid, 'EI']) elif self.packet[0] in (0x18, 0x19, 0x28, 0x29, 0x38, 0x48, 0x58, 0x68, 0x78, 0x85, 0xa4, 0xc4, 0xe2): # Proprietary self.putp(['Proprietary', 'P']) else: # Unknown self.putp(['Unknown', '?']) self.put(self.bytesi[-1], self.samplenum, self.out_ann, [6, ['Checksum OK', 'OK']] if \ calc_checksum(self.packet) == self.packet[-1] else [6, ['Checksum error', 'ERR']]) def process_byte(self): self.put(self.bytestart, self.bitsi[0], self.out_ann, ([2, ['Start bit', 'Start', 'S']]) if self.bits[0] == 0 else ([1, ['Start error', 'Start err', 'SE']])) databits = self.bits[1:9] data = bits_to_uint(databits) parity = reduce(lambda i, v: (i + v) % 2, databits, 1) self.put(self.bitsi[0], self.bitsi[8], self.out_ann, [4, ['%02x' % data]]) self.put(self.bitsi[8], self.bitsi[9], self.out_ann, ([3, ['Parity bit', 'Parity', 'P']]) if self.bits[9] == parity else ([1, ['Parity error', 'Parity err', 'PE']])) self.put(self.bitsi[9], self.bitsi[10], self.out_ann, ([3, ['Stop bit', 'Stop', 'S']]) if self.bits[10] == 1 else ([1, ['Stop error', 'Stop err', 'SE']])) self.bytesi.append(self.bytestart) self.packet.append(data) if self.packet_len(self.packet[0]) + 2 == len(self.packet): self.process_packet() self.bytesi.clear() self.packet.clear() def add_bit(self, bit): self.bits.append(bit) self.bitsi.append(self.samplenum) if self.state == 'IDLE' and len(self.bits) >= 5 and \ self.bits[-5:] == [1, 1, 1, 1, 0]: self.state = 'DATA' self.bytestart = self.bitsi[-2] self.bits = [0] self.bitsi = [self.samplenum] self.packet.clear() elif self.state == 'DATA' and len(self.bits) == 11: self.process_byte() self.bytestart = self.samplenum self.bits.clear() self.bitsi.clear() if self.state != 'IDLE': self.put(self.lastbit, self.samplenum, self.out_ann, [0, ['%d' % bit]]) self.lastbit = self.samplenum def handle_transition(self, l, htl): self.deq.append(l) if len(self.deq) >= 2 and \ (self.in_tolerance(self.deq[-1] + self.deq[-2]) or \ htl and self.in_tolerance(l * 2) and \ self.deq[-2] > 1.25 * self.bit_width): self.add_bit(1) self.deq.clear() elif self.in_tolerance(l): self.add_bit(0) self.deq.clear() elif l > (1.25 * self.bit_width): self.state = 'IDLE' self.bytesi.clear() self.packet.clear() self.bits.clear() self.bitsi.clear() def decode(self): if not self.samplerate: raise SamplerateError('Cannot decode without samplerate.') (qi,) = self.wait() self.handle_transition(self.samplenum, qi == 0) while True: prev = self.samplenum (qi,) = self.wait({0: 'e'}) self.handle_transition(self.samplenum - prev, qi == 0)